EP3816367A1 - Formwork support - Google Patents

Abstract

1. Formwork prop (1) with an outer support part (2) and a telescopic inner support part (3), the inner support part (3) having an anti-rotation section (14) and the outer support part (2) an anti-rotation area (4) with a first inner contour (17), the anti-rotation area (4) of the outer support part (2) cooperating with the anti-rotation section (14) of the inner support part (3) when the inner support part (3) is telescoped in such a way that the inner support part (3) is rotated by its longitudinal axis is blocked with respect to the outer support part (2), the outer support part (2) having a guide region (6) with a second inner contour (18) different from the first inner contour (17) for guiding the inner support part (3).

Description

The invention relates to a formwork prop with an outer pillar part and a telescopic inner pillar part, the inner pillar part having an anti-rotation section and the outer pillar part having an anti-rotation area with a first inner contour Support part cooperates that a rotation of the inner support part about its longitudinal axis relative to the outer support part is blocked.

The invention also relates to a ceiling formwork for producing a ceiling element with at least one formwork panel and at least one formwork support.

Formwork props of the type mentioned are used on construction sites for the production of ceilings. For this purpose, the formwork props are set up using a formwork plan and aligned with one another. When aligning the formwork props, particular attention must be paid to their orientation to one another. Above all, the prop heads should be aligned parallel to the head ends of the formwork props in order to enable the placement of transverse and longitudinal girders as well as formwork panels in the next work step. After the slab formwork has been erected, concrete is poured onto the formwork panels. The load of the concrete is diverted downwards into the ground via the formwork supports.

The DE 201 22 664 U1 shows a formwork prop. The formwork prop has an outer and an inner prop part which can be pulled out to extend the formwork prop. To lock the two support parts, the outer and inner support parts each have locking holes through which a locking bolt can be passed. However, in this prior art, the support parts can be rotated with respect to one another during telescoping.

Another formwork prop is from the DE 94 21 029 U1 known. This formwork prop also has an outer and an inner prop part located therein, on both Support parts are provided for locking hole pairs with opposite locking holes through which a locking bolt can be passed. Here, too, the two support parts can be rotated during telescoping.

Furthermore, from the DE 10 2012 211 384 A1 a formwork prop is known in which rotations of the inner prop part relative to the outer prop part are blocked when telescoping. However, the disadvantage of the formwork prop shown is that the formwork prop has a complicated structure and is therefore expensive to manufacture.

In the case of formwork props without an anti-twist device, a lot of time is lost when erecting the formwork props, since the prop parts in the telescoped position must be oriented to one another in such a way that the securing bolt can be passed through the securing holes in the inner and outer prop part. At the same time, when setting up the formwork props, as already explained above, care must be taken that the top plates of the same row of formwork props have the same orientation so that later transverse and longitudinal beams can be placed. In the case of formwork props without an anti-twist device, these work steps must be carried out by hand, which is made even more difficult by the heavy weight of the formwork props.

Known formwork props with anti-rotation locks, on the other hand, have a comparatively complex structure compared to formwork props without anti-rotation locks, which makes production and handling more difficult and increases weight. However, formwork props that are easy to manufacture, are easy to operate, have a low susceptibility to errors, can withstand high loads and are low in weight would be desirable.

It is therefore the object of the present invention to at least reduce or completely eliminate the disadvantages of the prior art. In particular, it is the object of the present invention to create a formwork prop that is easy to use and easy to manufacture, which facilitates the alignment and locking of the prop parts with structurally simple means and which can be telescoped quickly in a simple manner.

This object is achieved by a form support of the type mentioned at the beginning with the features of claim 1. Preferred embodiments are specified in the dependent claims.

According to the invention, the outer support part has a guide area with a second inner contour different from the first inner contour for guiding the inner support part. The telescoping of the formwork prop is advantageously facilitated by the guidance of the inner support part in the guide area. The guide area of the outer support part can expediently encompass the entire outer circumference of the inner support part. For this purpose, the second inner contour can be adapted to the outer contour of the inner support part and essentially correspond to this in terms of shape and size. The second inner contour can differ from the first inner contour, for example in terms of size and / or shape. The second inner contour is preferably tapered compared to the first inner contour. In addition to guiding the inner support part when telescoping, the formwork prop according to the invention prevents twisting of the inner support part relative to the outer support part, preferably by means of a positive fit, by the interaction of the anti-rotation section and the anti-rotation protection area. In other words, the inner and outer support parts of the formwork prop according to the invention are always oriented in the same way with respect to one another and therefore always have the same rotational position with respect to one another when used as intended. The formwork prop according to the invention is therefore secured against rotation. As a result, the prop parts can be locked in place more easily and, above all, more quickly, which reduces the time required to set up the formwork props. A particular advantage of the always the same orientation of the inner and outer support part is that, if there are securing holes, it is easier to pass through a securing bolt for locking purposes. The anti-rotation area of the outer support part is that area which, by interacting with the anti-rotation section of the inner support part, blocks rotation of the inner support part with respect to the outer support part, but at the same time a translational displacement of the inner support part relative to the outer support part in the longitudinal direction of the formwork support allowed. The anti-rotation area preferably adjoins the guide area and merges into it. The guide area can in particular be arranged in an upper end area of the outer support part.

For the purposes of this disclosure, directions such as “up”, “down” and “outside” relate to the intended use of the formwork prop, in which the formwork prop stands on a contact surface and the “top” longitudinal and cross members can be placed on the formwork prop. "Inward" means towards the longitudinal axis.

According to the invention, the anti-rotation area of the outer support part has a first inner contour that is different from the second inner contour. The first inner contour can have a polygonal shape, for example. It can also be provided, for example, that the outer support part has an inwardly protruding anti-rotation element in the anti-rotation area, which cooperates with the anti-rotation section of the inner support part. In a preferred embodiment, the inner contour is essentially the same in the entire anti-rotation area. The inner contour is also preferably essentially the same in the entire guide area, with the exception of a possible transition area to the anti-rotation area. However, this does not necessarily have to be the case. It is important that the guide area has a second inner contour that is different from the first inner contour. The first inner contour is intended to block rotation of the inner support part, while the second inner contour enables the inner support part to be guided. In this disclosure, the "inner contour" is to be understood as the inner boundary of a cross section. Accordingly, an outer contour designates the outer edge of a cross section. The first inner contour accordingly designates the inner edge of a cross section of the outer support part in the anti-rotation area, possibly with any anti-rotation elements. The second inner contour accordingly designates the inner edge of a cross section of the outer support part in the guide area. In order to save weight, the inner support part is preferably designed to be hollow. In addition, the inner support part can be made in one piece, optionally with joint connections, be trained. The inner and outer support parts are preferably made of metal, more preferably of steel. It is particularly preferred if the inner and outer support parts are made of different materials. It can also be provided that the outer support part has an area with an essentially circular inner contour and / or outer contour at the end opposite the guide area. This makes it easier to weld on a plate, in particular a base plate.

In one embodiment it can be provided that the inner support part has the anti-rotation section and a pull-out section. The anti-rotation section can be connected to the pull-out section and, in particular, merge into it. The pull-out section and the anti-rotation section can be in one piece. The pull-out section is that section that can be pulled out of the outer support part when telescoping, thereby lengthening the formwork support. However, the anti-rotation section and part of the pull-out section can also remain in the outer support part in the telescoped state for the purpose of stability and security. In another embodiment it can be provided that the anti-rotation section extends essentially over the entire length of the inner support part. With regard to the guide area of the outer support part, it can be provided that the second inner contour essentially corresponds to the outer contour of the inner support part, possibly the outer contour of the pull-out section of the inner support part. Among other things, the inner support part or the pull-out section can essentially have a circular outer contour and the second inner contour accordingly also have a circular shape. The guide area can also have an outer contour which corresponds in shape to the second inner contour. The anti-rotation area can also have an outer contour that corresponds to the shape of the first inner contour.

In a preferred embodiment it is provided that the second inner contour has a circular shape and is preferably tapered compared to the first inner contour. "Tapered" in this context means that of the second inner contour limited area is smaller than the area bounded by the first inner contour. It is advantageous if the shape of the second inner contour corresponds to the shape of the outer contour of the inner support part, in particular of a pull-out section. The second inner contour, which is tapered with respect to the first inner contour, can advantageously also prevent foreign bodies from entering the interior of the formwork prop.

In order to simplify production and handling, the anti-rotation area and the guide area can be designed in one piece and, in particular, merge into one another in a stepless manner. In particular, the anti-rotation area and the guide area can have been produced from a single workpiece, possibly with joint connections. This can be achieved in particular by reshaping a semi-finished product. Accordingly, the anti-rotation area and the guide area are connected to one another without a joint. In this context, stepless means that a transition area between the guide area and the anti-rotation area is free of projections, gradations and offsets, among other things.

In a preferred embodiment it is provided that the anti-rotation section has at least one anti-rotation indentation and the outer support part in the anti-rotation area has at least one anti-rotation indentation, the anti-rotation indentation being displaceable when telescoping the inner support part along the anti-rotation indentation and a rotation of the inner support part around its longitudinal axis blocked. The anti-rotation indentation thus interacts with the anti-rotation indentation of the outer support part in such a way that rotations about the longitudinal axis are blocked, but translational movements in the longitudinal direction of the formwork support are made possible. The anti-rotation indentation can slide in particular in the anti-rotation indentation. The anti-rotation bulge preferably projects radially outward from the inner support part. The anti-rotation bulge can be, among other things, a pin, a corner, an edge or a curvature. The anti-rotation indentation is preferably elongated and oriented in the direction of the longitudinal axis of the formwork prop.

The anti-rotation indentation can be located on the inside of the outer support part. The inside of the outer support part is formed by the inner wall of the outer support part. The indentation preventing rotation is preferably arched outwards and can be formed, for example, by a groove or an edge. The number of indentations preventing rotation is preferably at least as high as the number of indentations preventing rotation. When telescoping, the anti-rotation indentation slides in the longitudinal direction of the formwork support in the anti-rotation indentation. The interaction of the anti-rotation indentation with the anti-rotation indentation, preferably by means of a form fit, blocks rotation of the inner and outer support parts with respect to one another. Of course, a small amount of play can be provided in order to prevent wedging and to facilitate telescoping. Alternatively, the arrangement can also be reversed, that is to say an anti-rotation indentation can be provided in the anti-rotation section and an anti-rotation indentation in the anti-rotation area. In this alternative embodiment, the anti-rotation indentation and the anti-rotation indentation are arched inward and the indentation protection against rotation slides along the indentation protection against rotation when telescoping.

It is favorable if the first inner contour has an n-cornered, preferably a regular n-cornered, in particular a hexagonal or octagonal shape, and the indentations preventing rotation, viewed in cross section, are formed through the n corners of the first inner contour. The inner contour can be the same in the entire anti-rotation area. The outer support part can advantageously be approximated to a circular shape due to the n-angular shape, which has a favorable effect on the stability of the entire formwork support. "n" is a natural number and denotes the number of corners. The corners form the anti-rotation indentations which are delimited by the edges connecting the corners. As already mentioned, the first inner contour designates the inner contour of the cross section of the outer support part, that is to say the contour of the inside or inner wall of the outer support part. In the anti-rotation area can the shape of the outer wall / outer contour can essentially correspond to the shape of the inner wall / inner contour.

For this purpose, it is favorable if the anti-rotation section of the inner support part has an n-angular, preferably a regular n-angular, in particular an essentially square, outer contour and the n corners of the outer contour, viewed in cross-section, each form an anti-rotation indentation, the corners preferably being rounded are. "n" in turn denotes a natural number and denotes the number of corners. The number of corners of the anti-rotation section can, however, differ from the number of corners of the anti-rotation area. In this embodiment there are thus n indentations preventing rotation, wherein at least one corresponding indentation preventing rotation can be provided for each indentation preventing rotation. The outer contour of the anti-rotation section denotes the external contour of the cross-section of the anti-rotation section. The outer contour can be the same in the entire anti-rotation section.

The outer support part preferably has a length of at least 80 cm, in particular at least 80.8 cm, 135.6 cm, 160.6 cm, 185.6 cm, 210.6 cm, 238.5 cm, 285.6 cm or 370 , 6 cm. The inner support part preferably has a length of at least 90 cm, in particular at least 90.9 cm, 145.7 cm, 170.7 cm, 195.7 cm, 220.7 cm, 245.7 cm, 295.7 cm or 380 cm , 7 cm.

In order to be able to utilize a large part of the length of the inner support part when telescoping, it is advantageous if the anti-rotation section is provided at an end region of the inner support part. The anti-rotation section can form the closure, that is to say the end, of the inner support part. The end region of the inner support part on which the anti-rotation section is provided is that which remains in the outer support part during telescoping and is not pulled out.

In a preferred position it is provided that the anti-rotation area extends over the distance covered by the anti-rotation area between a fully telescoped area and a fully retracted position of the inner support member. The fully inserted position is that position in which the inner support part is pushed into the outer support part the furthest, in particular essentially completely. The fully telescoped position is a position in which the inner support part is pulled out of the outer support part to extend the formwork support, but is still at least partially in the outer support part so as not to impair the function of the formwork support.

Preferably, the largest outside diameter of the anti-rotation section corresponds essentially to the largest internal diameter of the anti-rotation area. The outer diameter of the anti-rotation section relates to its cross section. The largest outside diameter usually corresponds to the longest diagonal. If, for example, the anti-rotation section has a square outer contour, the largest outer diameter is the diagonal of the square. In the case of an n-gon, the largest diameter would be the longest diagonal between two corners. The same applies to the largest inner diameter of the anti-rotation area, which relates to the cross section of the outer support part, more precisely, its inner side or the first inner contour.

In order to block complete extension of the inner support part, the inner support part can have an extension section and the guide region can have an inner diameter which essentially corresponds to the largest outer diameter of the extension section. The largest outside diameter of the anti-rotation section is expediently larger than the largest outside diameter of the pull-out section. The anti-rotation section can therefore not be pushed through the guide area. The diameters in turn relate to the cross-sections of the respective elements. The guide area blocks the anti-rotation section from being pulled out. The guide area preferably has an essentially circular inner contour.

If an extension section is present, this can have an essentially circular outer contour in order to simplify the production of the inner support part and to increase the stability of the formwork support as a whole. The outer contour of the pull-out section designates the outer contour of the cross-section of the pull-out section. The outer contour of the pull-out section is preferably the same along its entire longitudinal extent. In a preferred embodiment, the pull-out section is formed by a round tube or a hollow cylinder. Alternatively, however, full cylinders can also be provided.

In a preferred embodiment it is provided that the inner support part has at least one securing hole and the outer support part, preferably in the guide area, has at least one holding recess, in particular an elongated holding hole, the formwork prop being in a telescoped position in which the securing hole and the at least one holding recess are superimposed lie that a securing bolt can be passed through the securing hole and the retaining recess at the same time. It is advantageous if a plurality of securing holes are arranged at regular intervals along a straight line along the longitudinal direction of the inner support part. If a pull-out section is provided, the securing hole is preferably provided therein. In particular, if the inner support part is hollow, several pairs of holes, each with two opposing securing holes, can be provided. The pull-out section is preferably designed as a tube which has several pairs of holes each with two opposing securing holes through which the securing bolt can be passed transversely to the longitudinal direction of the inner support part from one side of the tube to the other. The outer support part preferably also has a pair of holes with two holding holes, in particular elongated holding holes, arranged on opposite longitudinal sides of the outer support part. If there are pairs of holes on the inner support part, they are advantageously oriented along the longitudinal axis of the inner support part in such a way that they slide past the elongated retaining holes when the formwork support is telescoped, so that the securing bolt can be passed through the inner and outer support part at the same time.

In order to lock the formwork prop, the outer prop part can be provided with a securing bolt in the region of the at least one holding recess, which can be passed through the at least one holding recess and the at least one securing hole. The securing bolt preferably has two opposing U-shaped sections with different curve radii. The U-shaped section with the smaller curve radius has a securing leg, which can be passed through the at least one holding recess and the at least one securing hole and thus locks the circuit support. With the U-shaped section with the larger curve radius, an unintentional removal of the securing bolt from the formwork prop can be prevented. If the outer support part has a pair of elongated holding holes, the securing bolt can be displaced therein in the longitudinal direction of the formwork support.

For fine adjustment of the formwork prop in the locked state, the outer prop part can have an external thread with a nut in one end area. The external thread is preferably located in the guide area. The mother is a so-called union nut. If at least a region of the elongated holding hole is arranged within the external thread, a locking bolt that can be displaced therein can be displaced in the longitudinal direction of the formwork support by turning the nut. The securing bolt is inserted into the elongated holding hole and rests on the nut. In order to prevent unintentional rotation, the nut can have a securing element that blocks rotation of the nut.

The object according to the invention is also achieved by a ceiling formwork of the type mentioned in the introduction, in which the at least one formwork prop is designed as described above.

• Fig. 1 zeigt eine Ausführungsvariante einer erfindungsgemäßen Schalungsstütze.
• Fig. 2 zeigt einen Teil einer erfindungsgemäßen Schalungsstütze.
• Fig. 3 zeigt einen Längsschnitt des Teils gemäß Fig. 2.
• Fig. 4 zeigt einen unteren Endbereich einer erfindungsgemäßen Schalungsstütze.
• Fig. 5 zeigt einen Querschnitt der Schalungsstütze in einem oberen Endbereich.
• Fig. 6A - Fig 6C zeigen jeweils unterschiedliche Stellungen einer erfindungsgemäßen Schalungsstütze.
• Fig. 7 zeigt eine erfindungsgemäße Deckenschalung mit mehreren gleichartigen Schalungsstützen.
• Fig. 8 zeigt eine alternative Ausführungsform der erfindungsgemäßen Schalungsstütze in einer seitlichen Ansicht.
• Fig. 9 zeigt die alternative Ausführungsform der erfindungsgemäßen Schalungsstütze in einer Ansicht von oben.
• Fig. 10 zeigt einen Längsschnitt der Schalungsstütze gemäß Fig. 8.

In the following, preferred embodiments of the formwork prop according to the invention and the ceiling formwork according to the invention are described in more detail with reference to figures, to which, however, they should not be restricted.

• Fig. 1 shows a variant of a formwork prop according to the invention.
• Fig. 2 shows part of a formwork prop according to the invention.
• Fig. 3 shows a longitudinal section of the part according to Fig. 2 .
• Fig. 4 shows a lower end region of a formwork prop according to the invention.
• Fig. 5 shows a cross section of the formwork prop in an upper end area.
• Figures 6A-6C each show different positions of a formwork prop according to the invention.
• Fig. 7 shows a ceiling formwork according to the invention with several similar formwork props.
• Fig. 8 shows an alternative embodiment of the formwork prop according to the invention in a side view.
• Fig. 9 shows the alternative embodiment of the formwork prop according to the invention in a view from above.
• Fig. 10 shows a longitudinal section of the formwork prop according to Fig. 8 .

Fig. 1 shows a formwork prop 1 according to the invention with an outer prop part 2 and an inner prop part 3 arranged therein. To adjust the length of the formwork prop 1, the inner prop part 3 can be pulled out of the outer prop part 2, ie telescoped. Thus, the formwork prop 1 can be brought from a fully retracted position into a fully telescoped position.

In the embodiment shown, the outer support part 2 has an anti-rotation area 4 with an octagonal outer contour and, in an upper end area 5, a guide area 6 with an essentially circular outer contour for guiding the inner support part 3. The outer contour of the guide area 6 is opposite to the outer contour of the anti-rotation area 4 tapered and has an external thread 7. Plates 8, namely a top plate 9 and a base plate 10, are located at both ends of the formwork prop 1. The base plate 10 is connected to a lower end of the outer prop part 2 opposite the guide area 6. The head plate 9 is connected to an end of the inner support part 3 protruding from the guide area 6.

As in Fig. 2 As can be seen in more detail, essentially the entire guide region 6 is surrounded on the outside by the external thread 7. The external thread 7 can be milled or stamped, for example. The guide area 6 with the essentially circular outer contour merges into the anti-rotation area 4 with that of the octagonal outer contour, preferably without a joint connection and in particular steplessly. The guide area 6 and the anti-rotation area 4 can in particular have been produced in one piece, ie from a single workpiece. It can be seen that the guide area 6 has a reduced outer diameter compared to the anti-rotation area 4. The transition area 11 between the anti-rotation area 4 and the guide area 6 is conically converging.

Furthermore, in Fig. 2 It can be seen that a holding recess 40 in the form of an elongated holding hole 12 is provided in the guide region 6, within the external thread 7. Opposite the elongated holding hole 12, that is to say on the other side of the guide region 6, a further, similar elongated holding hole 12 is provided (not visible). The two elongated holding holes 12 together form a pair of elongated holding holes. To lock the formwork prop 1, the inner prop part 3 has several securing holes 13. Two securing holes 13 located on opposite sides of the inner support part 3 in turn form a pair of holes. A plurality of such pairs of holes are arranged one below the other along a straight line on the inner support part 3. With the help of the securing holes 13, the elongated holding holes 12 and a securing bolt (not shown), it is possible to lock the formwork prop 1 in a telescoped position, but displacements of the securing bolt within the elongated holding holes 11 are possible. For locking, the formwork prop 1 is brought into a position in which the elongated holding holes 12 lie over a pair of holes made up of two securing holes 13 and thus the securing bolt can be passed through the elongated retaining holes 12 and securing holes 13. A union nut 31 (see Fig. 5 ) be provided on which the securing bolt can rest and which has an internal thread that engages in the external thread 7. By turning the union nut 31, the position of the securing bolt in the elongated retaining holes 12 can be changed. The locking procedure is described below Fig. 5 explained.

Fig. 3 shows part of the formwork prop 1 in longitudinal section. It can be seen here that the inner support part 3 in the embodiment shown has an anti-rotation section 14 and a pull-out section 15. The anti-rotation section 14 is provided in an end region 16 of the inner support part 3. In the illustration shown, the pull-out section 15 is formed by a hollow round tube and accordingly has an essentially circular outer contour over its entire longitudinal extent. The pull-out section 15 is that section which can be passed through the guide area 6 and thus extends the formwork prop 3 when telescoping. In the embodiment shown, a part of the pull-out section 15 will always be covered by the guide area 6, since the anti-rotation section 14 cannot be passed through the guide area 6 due to its size. In Fig. 2 and Fig. 3 It can also be seen that the anti-rotation area 4 has a first inner contour 17 and the guide area 6 has a second inner contour 18 different from the first outer contour 17 (covered by the inner support part 2), the second inner contour 18 preferably tapering compared to the first inner contour 17, i.e. smaller , is. The guide area 6 thus has a smaller inner end diameter than the anti-rotation area 4. In this embodiment, the inner contour is the same in the entire guide area 6 and in the entire anti-rotation area 4. However, this does not necessarily have to be the case. It is important that the guide area 6 has a second inner contour 17 that is different from the first inner contour 17. The first inner contour 17 is intended to block rotation of the inner support part while the second inner contour 18 enables the inner support part 3 to be guided. The first inner contour 17 of the anti-rotation area 4, like its outer contour, has an octagonal shape. The second inner contour 18 of the guide region 6, like its outer contour, has an essentially circular shape. The inside diameter of the guide area 6 corresponds essentially to the largest outside diameter of the pull-out section 15, it being possible for a slight play to be provided between the pull-out section 15 and the guide area 6.
The anti-rotation section 14 is designed to block a rotation of the inner support part 3 with respect to the outer support part 2, but allow translational displacements of the inner support part 3 with respect to the outer support part 2 in the longitudinal direction of the formwork support 1. For this purpose, the anti-rotation section 14 has several, in the exemplary embodiment shown, four, anti-rotation bulges 19. The anti-rotation indentations 19 slide in elongated anti-rotation indentations 20 on an inner side 21 of the outer support part 2 in the anti-rotation area 4, the anti-rotation indentations 20 being oriented in the longitudinal direction of the formwork prop 1. The inner side 21 is formed by the inner wall of the outer support part 2.

Like in particular from Fig. 4 As can be seen, the outer contour of the anti-rotation section 14 has the shape of a square with rounded corners 22, the corners 22 forming the anti-rotation bulges 19. The largest diameter of the anti-rotation section 14, in the illustrated case the diagonal of the square of the outer contour, is greater than the diameter of the cross section of the pull-out section 15.

As seen in Fig. 5 is shown, the outer support part 2 in the anti-rotation section 4 has not only a regular octagonal outer contour, but also a regular octagonal first inner contour 17. The corners 23 of the first inner contour 17, viewed in cross section, form the anti-rotation indentations 20. The Anti-rotation indentations 19 slide in the longitudinal direction in the anti-rotation indentations 20, which, with the exception of the guide region 6, extend essentially over the entire outer support part 2. The anti-rotation section 14 is dimensioned in such a way that the anti-rotation bulges 19, viewed in cross section, are blocked by the edges 24 connecting the corners 23 of the outer support part 2 and forming the corners 23 when the inner support part 3 is rotated. The largest outer diameter of the anti-rotation section 14 advantageously corresponds essentially to the largest internal diameter of the anti-rotation area 4 of the outer support part 2. The corners 22 of the anti-rotation section 14 therefore lie in the corners 23 of the outer support part 2 and are secured against twisting by the edges 24.

In the exemplary embodiment shown, the anti-rotation indentations 20 extend from the end of the outer support part 2 opposite the guide area 6 to the guide area 6. In order to prevent the inner support part 3 from being pulled out completely on one side of the formwork prop 1, the guide area 6 or the second inner contour 18 has a smaller inner diameter than the largest outer diameter of the anti-rotation section 14. On the other side of the formwork prop 1, the base plate 10 prevents the inner prop part 3 from being pulled out.

In order to lock the inner support part 3 in a telescoped position, the formwork prop 1 shown is in accordance with FIG Fig. 5 a securing bolt 25 is provided. The securing bolt 25 shown has two opposing U-shaped sections 26, 27 with different curve radii. The U-shaped section 26 with the smaller curve radius has a securing section 28, while the U-shaped section 27 with the larger curve radius has a gripping section 29. A leg 30 of the securing section 28 is designed to be passed through the elongated holding holes 12 and the securing holes 13 and to lock the formwork prop 1. This leg 30 of the securing section 28 thus forms the "actual" securing bolt. With the gripping section 29, the displacement of the securing bolt 25 is facilitated. The safety bolt 25 is displaceable in the longitudinal direction in the elongated holding holes 12.

To adjust the height of the formwork prop 1, a union nut 31 can be provided. The union nut 31 has an internal thread (not shown) and is arranged on the external thread 7 and can be moved up and down in the longitudinal direction of the formwork prop 1 by twisting it. When the securing bolt 25 is inserted into the elongated retaining holes 12 which are arranged in the external thread 7, it can bear on the union nut 31. By turning the union nut 31, the securing bolt 25 is displaced in the longitudinal direction of the elongated holes 12. When the formwork prop 1 is loaded, the force is transmitted from the inner prop part 3 via the securing bolt 25 and the union nut 31 to the outer prop part 2. In order to fix the union nut 31, it can have a securing element 32 which, when activated, prevents the union nut 31 from rotating.

Figures 6A-C show the formwork prop 1 in different positions, with in Figure 6A the inner support part 3 is pushed the furthest into the outer support part 2. The formwork prop 1 could be pushed in even further by turning the union nut 31 or removing the securing bolt 25. Figure 6B shows a more extended position of the formwork prop 1. Figure 6C shows an even more extended position. Another pulling out would be in accordance with the position Figure 6C no longer possible, since the anti-rotation section 14 is already in contact with the guide area 6.

Fig. 7 shows a ceiling formwork 33 according to the invention with a large number of similar formwork props 1. The formwork props 1 are arranged in parallel rows and each have a foldable tripod 34 in the lower area for stabilization and alignment. On the head plates 9 of the formwork props 1, brackets 35 are provided, which secure the longitudinal beams 36 in the form of I-beams. Cross members 37 load on the longitudinal members 36 at right angles, so that the load of the concrete (not shown) to be poured later is carried evenly. On the cross members 37 there are finally formwork panels 38, on which the concrete is poured to create a ceiling element.

Fig. 8 shows an alternative embodiment of the formwork prop 1. The thread 7 is not shown. In this embodiment, the inner support part 3 is formed by an n-cornered tube. The anti-rotation section 14 of the inner support part 3 extends in this embodiment essentially over the entire length of the inner support part 3. The anti-rotation area 4 of the outer support part 2 has an anti-rotation element 39 in the form of an indentation which protrudes inward from the outer support part 2. The anti-rotation element 39 interacts with the anti-rotation section 14 of the inner support part 3 in such a way that a rotation of the inner support part 3 during telescopic copying is blocked by positive locking. The first inner contour 17 is defined here by the inner wall of the outer support part 2 and the anti-rotation elements 39 and differs from the second inner contour 18 of the guide area. As in the first embodiment, the second inner contour 18 is essentially circular.

Fig. 9 shows the formwork prop 1 in the alternative embodiment in a view from above.

Fig. 10 shows a longitudinal section of the embodiment according to FIG Fig. 8 .

Claims (15)

Formwork prop (1) with an outer pillar part (2) and a telescopic inner pillar part (3), the inner pillar part (3) having an anti-rotation section (14) and the outer post part (2) an anti-rotation area (4) with a first inner contour (17 ), the anti-rotation area (4) of the outer support part (2) interacting with the anti-rotation section (14) of the inner support part (3) when the inner support part (3) is telescoped in such a way that a rotation of the inner support part (3) about its longitudinal axis is blocked with respect to the outer support part (2), characterized in that the outer support part (2) has a guide area (6) with a second inner contour (18) different from the first inner contour (17) for guiding the inner support part (3). Formwork prop (1) according to claim 1, characterized in that the second inner contour (18) has a circular shape and is preferably tapered compared to the first inner contour (17). Formwork prop (1) according to Claim 1 or 2, characterized in that the anti-rotation area (4) and the guide area (6) are designed in one piece and in particular merge steplessly into one another. Formwork prop (1) according to one of claims 1 to 3, characterized in that the anti-rotation section (14) has at least one anti-rotation indentation (19) and the outer support part (2) in the anti-rotation area (4) has an anti-rotation indentation (20), wherein the anti-rotation indentation ( 19) is displaceable when telescoping the inner support part (3) along the anti-rotation indentation (20) and blocks rotation of the inner support part (3) about its longitudinal axis with respect to the outer support part (2). Formwork prop (1) according to claim 4, characterized in that the first inner contour (17) is an n-cornered, preferably one has a regular n-cornered, in particular a 6- or 8-cornered, cross-sectional shape and the anti-rotation indentations (20) are formed by the n corners (23) of the first inner contour (17). Formwork prop (1) according to claim 4 or 5, characterized in that the anti-rotation section (14) of the inner prop part (3) has an n-angular, preferably a regular n-angular, in particular a substantially square, outer contour and the n corners ( 22) of the outer contour each form an anti-rotation bulge (19), the corners (22) preferably being rounded. Formwork prop (1) according to one of Claims 1 to 6, characterized in that the anti-rotation section (14) is provided at an end region (16) of the inner support part (3). Formwork prop (1) according to claim 7, characterized in that the anti-rotation area (4) extends over the distance covered by the anti-rotation section (14) between a fully telescoped and a fully retracted position of the inner support part (3). Formwork prop (1) according to one of claims 1 to 8,
characterized in that the largest outside diameter of the anti-rotation section (14) essentially corresponds to the largest internal diameter of the anti-rotation area (4). Formwork prop (1) according to one of claims 1 to 9,
characterized in that the inner support part (3) has a pull-out section (15) and the guide region (6) has a smallest inner diameter which essentially corresponds to the largest outer diameter of the pull-out section (15). Formwork prop according to one of Claims 1 to 10, characterized in that the inner prop part (3) has at least one securing hole (13) and the outer prop part (2), preferably in the guide area (6), has at least one retaining recess (40), in particular an elongated retaining hole (12 ), wherein the formwork prop (1) is in a telescopic position in which the at least one securing hole (13) and the holding recess (40) lie one above the other in such a way that a securing bolt (25) can be passed through the at least one securing hole (13) and the holding recess (40) at the same time. Formwork prop (1) according to claim 11, characterized in that the outer prop part (2) in the region of the at least one retaining recess (40) has the securing bolt (25) which can be passed through the retaining recess (40) and the at least one securing hole (13) is. Formwork prop (1) according to claim 12, characterized in that the securing bolt (25) has two opposing U-shaped sections (26, 27) with different curve radii, the U-shaped section (27) with the larger curve radius having a gripping section (29 ) and the U-shaped section (26) with the smaller curve radius represents a securing section (28), the securing section (28) having a leg (30) which can be inserted into the holding recess (40) and the securing hole (13). Formwork prop (1) according to one of Claims 1 to 13, characterized in that the outer prop part (2) has an external thread (7) with a nut (31) in an end region (5), preferably in the guide region (6). Ceiling formwork (33) for producing a ceiling element with at least one formwork panel (38) and at least one formwork prop (1), characterized in that the at least one formwork prop (1) is designed according to one of claims 1 to 13.

Images